Method of Examining the Electrical Properties of Objects using Electric Fields

ABSTRACT

The electrical properties of objects are examined, using electric fields. An object is arranged on an apparatus having a first electrode ( 201 ) and a second electrode ( 202 ). The first electrode is energised during a first strobing operation of a scanning-cycle and the second electrode is monitored during this first strobing operation. Thereafter, during a second strobing operation, the second electrode is energised and the first electrode is monitored.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a divisional application of U.S. patent applicationSer. No. 16/185,447, filed on Nov. 9, 2018, which claims priority fromUnited Kingdom Patent Application number 1718678.4, filed on Nov. 11,2017. The whole contents of U.S. patent application Ser. No. 16/185,447and United Kingdom Patent Application number 1718678.4 are incorporatedherein by reference.

BACKGROUND OF THE INVENTION

The present invention relates to a method of examining electricalproperties of objects using electric fields.

It is known to examine electrical properties of objects using electricfields, as described in U.S. Pat. No. 8,994,383, assigned to the presentapplicant. Electrodes may be supported by a dielectric membrane. Astrobing voltage may be applied to energise a first input electrode as atransmitter and an output voltage may be monitored on an output receiverelectrode. An external electric field is generated that may pass throughan object, such that an output signal will be influenced by electricalproperties of the object, including the permittivity of the object. Theoutput signal is usually sampled at a sample point during each strobingoperation to facilitate digital processing.

A problem with known systems is that it can be difficult to obtainsufficient information to fully identify properties of an object.

BRIEF SUMMARY OF THE INVENTION

According to a first aspect of the present invention, there is provideda method of examining electrical properties of objects, using electricfields, comprising the steps of: arranging an object on an apparatushaving a first electrode and a second electrode; energising said firstelectrode during a first strobing operation of a scanning cycle;monitoring said second electrode during said first strobing operation;energising said second electrode during a second strobing operation ofsaid scanning cycle; and monitoring said first electrode during saidsecond strobing operation.

Thus, in this way, the first electrode is not dedicated as a transmitterelectrode and the second electrode is not dedicated as a receiverelectrode. Each of these electrodes can perform both functions, therebyenhancing the amount of information that can be derived from theapparatus, without making significant modifications to the apparatusitself.

In an embodiment, additional electrodes are provided. The method maythen further comprise the steps of energising all of the additionalelectrodes during respective strobing operations of the scanning cycle;and monitoring all of said additional electrodes at appropriate strobingoperations of the scanning cycle.

Embodiments of the invention will be described, by way of example only,with reference to the accompanying drawings. The detailed embodimentsshow the best mode known to the inventor and provide support for theinvention as claimed. However, they are only exemplary and should not beused to interpret or limit the scope of the claims. Their purpose is toprovide a teaching to those skilled in the art.

Components and processes distinguished by ordinal phrases such as“first” and “second” do not necessarily define an order or ranking ofany sort.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1 shows an environment in which an examination apparatus isdeployed;

FIG. 2 details the examination apparatus identified in FIG. 1;

FIG. 3 shows a schematic representation of the functionality of theapparatus shown in FIG. 2;

FIG. 4 illustrates the generation of electric fields;

FIG. 5 shows an alternative configuration of the apparatus shown in FIG.3;

FIG. 6 illustrates electric fields generated in response to theconfiguration of FIG. 5;

FIG. 7 shows an alternative configuration of the apparatus shown in FIG.3 and FIG. 5;

FIG. 8 shows resulting electric fields from the configuration of FIG. 7;

FIG. 9 illustrates an examination period;

FIG. 10 shows a schematic representation of the examination apparatusshown in FIG. 2;

FIG. 11 shows a schematic representation of a strobing circuit of thetype identified in FIG. 9;

FIG. 12 shows an example of a multiplexing environment of the typeidentified in FIG. 10;

FIG. 13 shows an example of a monitoring circuit of the type identifiedin FIG. 10;

FIG. 14 shows an overview of procedures performed by the processoridentified in FIG. 10;

FIG. 15 details procedures for scanning electrodes identified in FIG.14; and

FIG. 16 shows an alternative examination apparatus.

DETAILED DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWINGS

FIG. 1

An examination apparatus 101 is shown in FIG. 1 for examining electricalproperties of objects, using electric fields. The examination apparatus101 communicates with a data processing system 102 via a datacommunication cable 103, possibly designed in accordance withestablished USB protocols.

FIG. 2

The examination apparatus 101 is shown in greater detail in FIG. 2. Itincludes a plurality of parallel electrodes, including a first electrode201 and a second electrode 202, along with a plurality of additionalelectrodes 203. Electrodes 201 to 203 are supported by a dielectricinsulating membrane 204 and the electrodes are then covered by aninsulating material to ensure that the surface of the examinationapparatus is non-conductive.

The examination apparatus 101 is arranged to examine the electricalproperties of entities, such as an object 205. In known systems of thetype illustrated in FIG. 2, electrodes have dedicated functionality; inthat they are either energised, to provide a transmitter electrode, ormonitored to provide a receiver electrode. Thus, in known systems, eachelectrode is identified exclusively as a dedicated input electrode or adedicated output electrode.

The present embodiment provides an apparatus in which a first electrode201 is configured to be energised during a first strobing operation of ascanning cycle and a second electrode 202 is configured to be monitoredduring this first strobing operation. Thus, in conventional systems, thefirst electrode 201 would be dedicated as a transmitter electrode andthe second electrode 202 would be dedicated as a receiver electrode.However, in accordance with the present invention, during part of thesame scanning cycle, the second electrode 202 is configured to beenergised during a second strobing operation and the first electrode 201is configured to be monitored during this second strobing operation.Thus, within the same overall scanning cycle, data is obtained by usingthe first electrode 201 as a transmitter and the second electrode 202 asa receiver. Subsequently, these roles are reversed, such that additionaldata is received by energising the second electrode 202 as thetransmitter, with the first electrode 201 being scanned as a receiver.To achieve this, additional electronics are required and operationsperformed by a microcontroller must ensure that any one electrode is notenergised and scanned simultaneously as part of the same strobingoperation.

In an embodiment, as illustrated in FIG. 2, the additional electrodes203 are also configured to be energised during respective strobingoperations, such that the first electrode 201, the second electrode 202and the additional electrodes are all configured to be monitored atappropriate strobing operations of a scanning cycle.

FIG. 3

In the embodiment of FIG. 2, the first electrode 201, the secondelectrode 202 and the plurality of additional electrodes 203 definesubstantially parallel tracks, as shown schematically in FIG. 3.Electric fields are generated between adjacent ones of said tracks, aswill be described with reference to FIG. 4. Alternative arrangements oftracks are possible, an example of which will be described withreference to FIG. 16.

As used herein, a scanning cycle consists of unique sequential strobingoperations performed in a particular order. During an examination, thescanning cycle may be repeated and characteristics of the scanning cyclemay be adjusted. However, without making any adjustments of this type,the cycle is repeated periodically at a rate primarily determined byelectrical characteristics of the examination apparatus 101, clock speedand the number of strobing operations performed within each cycle. Inthis embodiment, a strobing operation consists of energising a selectedelectrode to generate an electric field. This in turn capacitivelycouples to other electrodes; such that the scanning operation iscompleted by selecting an adjacent electrode to be monitored. Thisprovides an output signal that is sampled and then processed within thedigital domain.

As previously stated, known apparatus dedicate each electrode to beingeither an input (transmitter) electrode or an output (receiver)electrode. In accordance with an embodiment of the present invention,any electrode 201 to 203 can be selected to receive an energising signalor can be selected to be monitored and thereby produce an output signal.

A schematic representation for achieving this functionality isillustrated by a switching device 301. The switching device 301 receivesinput energising signals on an input line 302. Similarly, the switchingdevice 301 provides output signals on an output line 303.

The first electrode 201 is connected to a first switch 304 within theswitching device 301. Similarly, the second electrode 202 is connectedto a second switch 305. In this embodiment, a third electrode 306, ofthe additional electrodes 203, is connected to a third switch 307. Afourth electrode 308 is connected to a fourth switch 309. A fifthelectrode 310 is connected to a fifth switch 311 and a sixth electrode312 is connected to a sixth switch 313. Similarly, a seventh switch 314connects to a seventh electrode 315, with an eighth electrode 316 beingconnected to an eighth switch 317.

Each of switches 304, 305, 307, 309, 311, 313, 314 and 317 includes afirst contact 318, a second contact 319 and a third contact 320. Foreach of the switches, the first contact 318 is connected to the inputline 302. Similarly, the third contact 320 is connected to the outputline 303. The second contact 319, positioned between the first contact318 and the third contact 320, does not provide a connection at all and,in this embodiment, presents an open circuit to its respective electrodesuch that, in the terminology of the art, the electrode is left floatingwhen connected to the second contact 319. In an alternative embodiment,the second contact 319 may be connected to ground.

In the configuration shown in FIG. 3, the first switch 304 connects theinput line 302 to the first electrode 201 such that, during the nextstrobing operation, the first electrode 201 will be energised.Furthermore, in the configuration of FIG. 3, the third contact 320 ofthe second switch 305 connects the second electrode 202 to the outputline 303. Thus, during a strobing operation identified above, the secondelectrode 202 will be monitored while the first electrode 201 isenergised. A schematic representation of this strobing operation, whenviewed in the direction of arrow 400, is illustrated in FIG. 4.

FIG. 4

A cross-sectional view of the examination apparatus of FIG. 2 isillustrated in FIG. 4, when viewed in the direction of arrow 400 (ofFIG. 3). The object 205 has been placed on the examination apparatus101. The first electrode 201 is shown in cross-section, along with thesecond electrode 202, the third electrode 306, the fourth electrode 309and the fifth electrode 311. In the embodiment, the apparatus extends tothe right to include electrodes 313, 314 and 317. The first electrode201, the second electrode 202 and the additional electrodes aresupported by the dielectric membrane 204. This is in turn covered by aninsulating coating 401, thereby insulating the electrodes 201, 202 etc.from the object 205.

A conducting ground plane 402 is provided to shield the apparatus fromexternal electrical noise. An intermediate layer 403 is also providedbetween the dielectric membrane 204 and the ground plane 402 that, in anembodiment, may include response enhancement properties.

During a strobing operation, an electric field is produced between thefirst electrode 201 and the second electrode 202, as illustrated byelectric field lines 404. These represent capacitive coupling, thatoccurs given that the first electrode 201 is providing the functionalityof a transmitter electrode and the second electrode 202 is providing thefunctionality of a receiver electrode. During a strobing cycle, thefirst electrode 201 is energised and the second electrode 202 ismonitored.

The electric field lines 402 show that the electric field penetrates theobject 205. A useful depth of penetration is indicated at 405. Thedistance between the electrodes is indicated at 406. Experimentsconducted by the inventor suggest that the useful depth of penetration405 is approximately half of the distance 406 between the electrodes.

FIG. 5

In this embodiment, for the next strobing operation of the scanningcycle, the first switch 304 is activated to connect the third contact320 to the first electrode 201. Similarly, the second switch 305 isactivated to connect the second electrode 202 to a second first contact501. Thus, in this configuration, electrode 202 now performs atransmitter function, with the first electrode 201 performing a receiverfunction.

FIG. 6

The result of this switching operation, from the configuration of FIG. 3to the configuration of FIG. 5, results in a reversal of functionality,such that the second electrode 202 becomes a transmitter and the firstelectrode 201 becomes a receiver.

Thus, as illustrated in FIG. 6, the direction of the electric fieldlines 404 has reversed.

FIG. 7

In this embodiment, for the next strobing operation, the first switch304 is activated, the second switch 305 is activated and the thirdswitch 307 is activated. The first switch 304 connects the firstelectrode 201 to the second contact 319, such that the first electrode201 will not contribute to the next strobing operation. Switch 305remains in position, connected to the second first contact 501, suchthat, again, the second electrode 202 will provide the functionality ofa transmitter. However, on this strobing operation, the third switch 307has been activated to connect a third electrode 701 to the output line303, thereby causing the third electrode 306 to provide thefunctionality of a receiver.

FIG. 8

Upon initiating a strobing operation for the configuration describedwith reference to FIG. 7, an electric field 801 is generated, asillustrated in FIG. 8. Thus, the second electrode 202 providestransmitter functionality and the third electrode 306 provides receiverfunctionality.

Thus, in this embodiment, each electrode sequentially adopts thefunctionality of a transmitter. When given this functionality, a firststrobing operation monitors an electrode immediately to the left,followed by a second strobing operation that monitors the electrodeimmediately to the right. The sequencing then advances and the roles ofthe electrodes are changed.

FIG. 9

During a working period, many objects may be examined. The duration ofan examination is illustrated in FIG. 9. Similar procedures areperformed for each object and a particular examination of an objectstarts by arranging the object on the apparatus, as described withreference to FIG. 2.

During an examination process 901, electrodes are energised sequentiallyand the procedure may be referred to informally as “scanning”. As usedherein, a complete scan cycle is performed when all unique combinationsof transmitters and receivers have been exercised. Thus, during theexamination 901, many scan cycles may be performed. For the purposes ofthis illustration, during examination procedure 901, a first scan cycle902 is performed, followed by a similar second scan cycle 903 and asimilar third scan cycle 904.

During each scan cycle, such as scan cycle 902, many strobing operationsare performed, including a first strobing operation 905, a secondstrobing operation 906, and a third strobing operation 907 etc. Eachstrobing operation is unique, in terms of the particular electrodeselected as the transmitter in combination with the particular electrodeselected as the receiver. Each strobing operation consists of energisingthe selected transmitter electrode and monitoring the selected receiverelectrode.

Due to capacitive coupling, each monitoring process monitors a voltageat the receiver electrode. To determine electrical properties ofobjects, a measurement is required. In a preferred embodiment, thismeasurement is achieved by performing a process of analog to digitalconversion, thereby allowing the result of this conversion to beprocessed within the digital domain.

In FIG. 9, strobing operation 905 takes place within a monitoredduration 908. Within the monitored duration 908, a sampling instant 909occurs, representing an instant within the monitored duration at whichan output voltage is sampled.

In order to optimise results received from the examination process, thesampling instant does not occur immediately following the generation ofan input strobing signal. Although, in an embodiment, a sharp,rapidly-rising strobing input signal is supplied to the transmitters,the shape of resulting output signals will not rise so steeply; as aresult of the electrical properties of the device and the electricalproperties of the objects. Thus, to optimise the value of theinformation derived from the procedure, the sampling instant 909 isdelayed by a predetermined delay period 910.

FIG. 10

A schematic representation of the examination apparatus 101 isillustrated in FIG. 10. This provides an apparatus for examiningelectrical properties of objects, using electric fields. A number ofsubstantially parallel electrodes are supported on a dielectricmembrane, as described with reference to FIG. 2. In the representationof FIG. 10, the dielectric membrane, with parallel electrodes, isincluded within a multiplexing environment 1001. In addition to thedielectric membrane, the multiplexing environment 1001 includes ade-multiplexer for selectively de-multiplexing multiplexed energisinginput voltage pulses for application to each of the electrodes, alongwith a multiplexer for selectively multiplexing output signals monitoredfrom each of the electrodes, as described with reference to FIG. 12.

A processor 1002, implemented as a microcontroller, controls thede-multiplexer and the multiplexer to ensure that the same electrodecannot both be energised and monitored during a strobing operation.

An energising circuit 1003 is energised by a power supply 1004 that inturn may receive power from an external source via a power inputconnector 1005. A voltage control line 1006 from (a digital to analogconvertor within) the processor 1002 to the energising circuit 1003allows the processor 1002 to control the voltage (and hence energy) ofenergising signals supplied to the multiplexing environment 1001, via astrobing line 1007. The timing of each strobing signal is controlled bythe microcontroller 1002 via a trigger signal line 1008.

An output from the multiplexing environment 1001 is supplied to ananalog processing circuit 1009 over a first analog line 1010. Aconditioning operation is performed by the analog processing circuit1009, allowing analog output signals to be supplied to themicrocontroller 1002 via a second monitoring line 1011. The processor1002 also communicates with a two way data communication circuit 1012,thereby allowing a data interface 1013 to connect with the datacommunication cable 103.

In operation, the processor 1002 supplies addresses over address busses1014 to the multiplexing environment 1001 in order to achieve thefunctionality described with reference to FIGS. 3 to 8. Thus, havingsupplied addresses to the multiplexing environment 1001, a strobingvoltage is supplied via strobing line 1007, resulting in an outputsignal being supplied to the processor 1002. At the processor 1002, ananalog input signal is sampled to produce a digital representation and,in an embodiment, this digital data is uploaded to the data processingsystem 102 via the data interface 1013.

FIG. 11

An example of the energising circuit 1003 is shown in FIG. 11. Theenergising circuit 1003 consists of a voltage control circuit 1101connected to a strobing circuit 1102 via a current limiting resistor1103.

A voltage input line 1104 receives energising power from the powersupply 1004 to energise an operational amplifier 1105. The operationalamplifier 1105 is configured as a comparator and receives a referencevoltage via feedback resistor 1106. This is compared against a voltagecontrol signal, received on the voltage control line 1006, to produce aninput voltage for the strobing circuit 1102.

In the embodiment of FIG. 11, the strobing circuit 1102 includes twobipolar transistors configured as a Darlington pair, in combination witha MOSFET. This creates strobing pulses with sharp rising edges and sharpfalling edges that are conveyed to the strobing line 1008.

FIG. 12

An example of a multiplexing environment 1001 is detailed in FIG. 12.The switching functionality, described with reference to FIG. 3, isachieved by the provision of a first multiplexing device 1201 and asecond multiplexing device 1202. In this alternative embodiment, adielectric membrane 1203 supports sixteen parallel electrodes 1204.

The address busses 1014 include an input address bus 1205 and an outputaddress bus 1206, for addressing the first multiplexing device 1201 andthe second multiplexing device 1202 respectively. The addressing spacefor the input address bus 1205 and the output address bus 1206 may besimilar, which may assist in terms of ensuring that the same addresscannot be supplied simultaneously to both the input address bus 1205 andthe output address bus 1206.

The first multiplexing device 1201 also includes a first enabling line1207. Similarly, the second multiplexing device 1202 includes a secondenabling line 1208. In operation, addresses are supplied to the inputaddress bus 1205 and to the output address bus 1206 but line selectiondoes not actually occur until the multiplexing devices receive arespective enabling signal.

The first multiplexing device 1201 receives an input pulse from theenergising circuit 1003 via the strobing line 1008. Multiple strobingoperations are performed, such that an input energising voltage issupplied sequentially to electrodes performing a transmitter function.Strobing signals are distributed to multiple inputs; therefore, thefirst multiplexing device 1201 should be seen as performing ade-multiplexing operation.

The second multiplexing device 1202 performs a multiplexing operation,in that multiple output signals are selected sequentially and thencombined onto the first monitoring line 1010 for reception by themonitoring circuit 1009. Thus, in this embodiment, the multiplexingenvironment is established by a single first multiplexing device forinput signals and a single second multiplexing device for outputsignals, both of which are connected to all sixteen of the availableelectrodes. Furthermore, if a greater number of electrodes are presentupon a dielectric membrane, it is possible for additional multiplexingdevices to be provided such that, for example, a pair of multiplexingdevices may provide the input de-multiplexing function and a furtherpair of multiplexing devices may provide the multiplexing outputfunction; provided that an appropriate addressing space has beenestablished.

During a strobing operation, an input address is supplied on the inputaddress bus 1205 and an output address is supplied on the output addressbus 1206. The addresses are enabled such that, at a particular point intime, the output multiplexer 1202 is enabled and as such is thenconfigured to monitor output signals on the addressed output electrodes.The selected input electrode is then energised by the application of astrobing pulse, which may be considered to occur at the start of arrow910 shown in FIG. 9.

A short, predetermined delay, for the duration of arrow 910, occursbefore the sampling instant 909 occurs; taking a sample of the voltagemonitored on the output electrode. In this embodiment, the firstmonitoring line 1010 applies an output analog voltage to the analogprocessing circuit 1009 for the duration of the strobing operation, suchas strobing operation 905. The analog voltage is conditioned by theanalog processing circuit 1009, which in turn supplies a conditionedvoltage to the processor 1002 via the second monitoring line 1011.Digital-to-analog conversion then takes place within the processor 1002,such that the point at which the sampling instant 909 occurs isdetermined by the processor.

FIG. 13

An example of an analog processing circuit 909 is illustrated in FIG.13. Signals received on the first monitoring line 1010 are supplied to abuffering amplifier 1301 via a decoupling capacitor 1302. During aninitial set-up procedure, a variable feedback resistor 1303 is trimmedto optimise the level of monitored signals supplied to the processor1002 via the second monitoring line 1011. A Zener diode 1304 preventsexcessive voltages being supplied to the processor 1002.

FIG. 14

An overview of procedures performed by the processor 1002 is illustratedin FIG. 14. After an initial switch-on, possibly initiated by the dataprocessing system 102, the sensor array is calibrated at step 1401. Thisenables a reference level to be established, prior to the application ofan object, such as object 205.

After the application of an object, the electrodes are scanned at step1402. As previously described, each scan consists of a plurality ofstrobing operations with each strobing operation consisting of a uniquecombination of transmitter electrode and receiver electrode.

At step 1403, data is processed and the degree of local data processingwill depend upon the processing capabilities provided by the processor1002.

In an embodiment, the level of received monitored signals may becompared against a reference and, where appropriate, a control voltageon the voltage control line 906 may be adjusted.

More sophisticated processing may be achieved by the data processingsystem 102, therefore the data is supplied as an output to the dataprocessing system 102 at step 1404. Thereafter, further scanning isperformed at step 1402 and the procedures are repeated until ade-energisation command is received.

FIG. 15

Procedures 1402 for scanning the electrodes are detailed in FIG. 15. Atstep 1501, an input electrode is selected; which would be the firstelectrode 201 on the first iteration. At step 1502 a question is askedas to whether there is an N minus one (N−1) electrode which, if present,is selected at step 1503. Thereafter, the input electrode N selected atstep 1501 is energised and the electrode before it, N minus one, ismonitored at step 1504.

On a first iteration, the first electrode will have been selected;therefore, an N minus one electrode does not exist. Consequently, thequestion asked at step 1502 will be answered in the negative.

At step 1505 a question is asked as to whether there is an N plus oneelectrode (N+1) which, when answered in the affirmative, results in aselection of this electrodes as a monitoring electrode at step 1506.Thus, at step 1507 electrode N is energised and electrode N plus one(N+1) is monitored. On the first iteration, an N plus one electrode ispresent, therefore the energisation at step 1507 is as illustrated inFIG. 4, with the first electrode 201 being a transmitter and the secondelectrodes 202 being a receiver. Thus, output data is generated.

Thereafter, a question is asked at step 1508 as to whether another inputelectrode is present which, when answered in the affirmative, results inthe next input being selected at step 1501. In this example, this willresult in the second electrode 202 being selected at step 1501 and thequestion then asked at step 1502 will be answered in the affirmative,given that the first electrode 201 will now be selected as the N minusone (N−1) electrode. Consequently, the second electrode 202 is energisedand the first electrode 201 is monitored, as illustrated in FIG. 6.

Thereafter, at step 1505 a question is asked as to whether there is an Nplus one (N+1) electrode, which would be answered in the affirmative;resulting in the third electrode 306 being selected at step 1506.Consequently, at step 1507, the second electrode 202 will be energisedand the third electrode 306 will be monitored, as illustrated in FIG. 8.Thereafter, the question asked at step 1508 will be answered in theaffirmative and the process will be repeated, this time with the thirdelectrode 306 being the energised transmitter electrode N.

Thus, the question asked at step 1508 will continue to be answered inthe affirmative until all of the electrodes have been selected. Thiswill result in the establishment of a complete cycle such that, at step1509, a question is asked as to whether the cycle is to repeat. Whenanswered in the affirmative, the first electrode is selected again atstep 1501.

The procedure provides a method of examining electrical properties ofobjects, using electric fields. An object is arranged on an apparatushaving a first electrode and a second electrode, as described withreference to FIG. 2. The first electrode is energised during a firststrobing operation of a scanning cycle and a second electrode ismonitored during this first strobing operation. Usually, this wouldestablish electrodes as being specifically dedicated for a transmittingoperation or a reception operation. However, by providing asophisticated multiplexing environment, as described with reference toFIG. 12, it is possible to then energise the second electrode during asecond strobing operation, while monitoring the first electrode duringthis second strobing operation; as part of the same scanning cycle.

FIG. 16

An alternative examination apparatus 1601 is shown in FIG. 16. A firstelectrode 1602 and a first plurality of additional electrodes provide afirst set of substantially parallel tracks; substantially similar to thearrangement described with respect to FIG. 12. However, the secondelectrode 1603 and a second plurality of electrodes provide a second setof substantially parallel tracks; where both sets of tracks are mountedon opposite sides of a dual-sided membrane 1604.

The second set of electrodes, including second electrode 1603, issubstantially orthogonal to the first set of electrodes, including thefirst electrode 1602, and electrically insulated therefrom. The firstelectrode and the first plurality of electrodes are energised(sequentially) while the second electrode and the second plurality ofelectrodes are sequentially monitored. Thereafter, the second electrodeand the second plurality of electrodes are energised while the firstelectrode and the first plurality of electrodes are monitored.

A first alternative multiplexing device 1605 supplies energising signalsto the first set of electrodes. A second alterative multiplexing device1606 receives output signals from the first set of electrodes.Similarly, a third alterative multiplexing device 1607 suppliesenergising signals to the second set of electrodes and a fourthalternative multiplexing device 1608 receives output signals from thesecond set of electrodes.

During a scanning cycle, the first alterative multiplexing device 1605is operative, in combination with the fourth alternative multiplexingdevice 1608, such that, for part of the cycle, the first set ofelectrodes are energised and the second set of electrodes are scanned.Thereafter, as part of the same cycle, the third alternativemultiplexing device 1607 is energised; thereby energising the second setof electrodes and the second alternative multiplexing device 1606 isaddressed.

1. A method of examining electrical properties of objects, usingelectric fields, comprising the steps of: arranging an object on anapparatus having a first electrode and a second electrode; energisingsaid first electrode during a first strobing operation of a scanningcycle; monitoring said second electrode during said first strobingoperation; energising said second electrode during a second strobingoperation of said scanning cycle; and monitoring said first electrodeduring said second strobing operation.
 2. The method of claim 1, whereinsaid apparatus includes a plurality of additional electrodes.
 3. Themethod of claim 2, further comprising the steps of: sequentiallyenergising each of said additional electrodes during respective strobingoperations of said scanning cycle; and for a selected energisedelectrode N, monitoring, when electrode N−1 is present, electrode N−1,and then monitoring, when electrode N+1 is present, electrode N+1 duringrespective strobing operations of said scanning cycle.
 4. The method ofclaim 1, further comprising the step of analysing data produced by saidmonitoring steps after performing a complete scanning cycle.
 5. Themethod of claim 4, further comprising the steps of: modifying a scanningcharacteristic in response to said analysing step; and conducting afurther scanning cycle.
 6. The method of claim 5, wherein said modifyingstep includes modifying said energising step.
 7. The method of claim 1,in which each strobing operation includes the energising step and themonitoring step, wherein: each said energising step includes applying aninput voltage pulse to a selected input electrode; and said monitoringstep includes sampling an output voltage received on a selected outputelectrode.
 8. The method of claim 2, in which each strobing operationincludes the energising step and the monitoring step, wherein: each saidenergising step includes applying an input voltage pulse to a selectedinput electrode; and said monitoring step includes sampling an outputvoltage received on a selected output electrode.
 9. The method of claim3, in which each strobing operation includes the energising step and themonitoring step, wherein: each said energising step includes applying aninput voltage pulse to a selected input electrode; and said monitoringstep includes sampling an output voltage received on a selected outputelectrode.
 10. The method of claim 5, in which each strobing operationincludes the energising step and the monitoring step, wherein: each saidenergising step includes applying an input voltage pulse to a selectedinput electrode; and said monitoring step includes sampling an outputvoltage received on a selected output electrode.
 11. The method of claim4, in which each strobing operation includes the energising step and themonitoring step, wherein: each said energising step includes applying aninput voltage pulse to a selected input electrode; and said monitoringstep includes sampling an output voltage received on a selected outputelectrode.
 12. The method of claim 7, wherein: said applying stepincludes applying said input voltage pulse via a de-multiplexingprocess; and said sampling step includes receiving an output voltage viaa multiplexing process.
 13. The method of claim 1, wherein: saidelectrodes define a plurality of parallel tracks; and said electricfields extend between adjacent parallel tracks.
 14. The method of claim2, wherein: said electrodes define a plurality of parallel tracks; andsaid electric fields extend between adjacent parallel tracks.
 15. Themethod of claim 3, wherein: said electrodes define a plurality ofparallel tracks; and said electric fields extend between adjacentparallel tracks.
 16. The method of claim 4, wherein: said electrodesdefine a plurality of parallel tracks; and said electric fields extendbetween adjacent parallel tracks.
 17. The method of claim 1, wherein:said electric fields extend between electrodes of a first set ofsubstantially parallel tracks that includes said first electrode andelectrodes of a second set of substantially parallel tracks thatincludes said second electrode; and said second set of substantiallyparallel tracks are substantially orthogonal to said first set ofsubstantially parallel tracks.
 18. The method of claim 2, wherein: saidelectric fields extend between electrodes of a first set ofsubstantially parallel tracks that includes said first electrode andelectrodes of a second set of substantially parallel tracks thatincludes said second electrode; and said second set of substantiallyparallel tracks are substantially orthogonal to said first set ofsubstantially parallel tracks.
 19. The method of claim 3, wherein: saidelectric fields extend between electrodes of a first set ofsubstantially parallel tracks that includes said first electrode andelectrodes of a second set of substantially parallel tracks thatincludes said second electrode; and said second set of substantiallyparallel tracks are substantially orthogonal to said first set ofsubstantially parallel tracks.